Functional and therapeutic analysis of hepatitis C virus NS3.4A protease control of antiviral immune defense

Chronic hepatitis C virus (HCV) infection is a major global public health problem. HCV infection is supported by viral strategies to evade the innate antiviral response wherein the viral NS3.4A protease complex targets and cleaves the interferon promoter stimulator-1 (IPS-1) adaptor protein to ablate signaling of interferon alpha/beta immune defenses. Here we examined the structural requirements of NS3.4A and the therapeutic potential of NS3.4A inhibitors to control the innate immune response against virus infection. The structural composition of NS3 includes an amino-terminal serine protease domain and a carboxyl-terminal RNA helicase domain. NS3 mutants lacking the helicase domain retained the ability to control virus signaling initiated by retinoic acid-inducible gene-I (RIG-I) or melanoma differentiation antigen 5 and suppressed the downstream activation of interferon regulatory factor-3 (IRF-3) and nuclear factor kappaB (NF-kappaB) through the targeted proteolysis of IPS-1. This regulation was abrogated by truncation of the NS3 protease domain or by point mutations that ablated protease activity. NS3.4A protease control of antiviral immune signaling was due to targeted proteolysis of IPS-1 by the NS3 protease domain and minimal NS4A cofactor. Treatment of HCV-infected cells with an NS3 protease inhibitor prevented IPS-1 proteolysis by the HCV protease and restored RIG-I immune defense signaling during infection. Thus, the NS3.4A protease domain can target IPS-1 for cleavage and is essential for blocking RIG-I signaling to IRF-3 and NF-kappaB, whereas the helicase domain is dispensable for this action. Our results indicate that NS3.4A protease inhibitors have immunomodulatory potential to restore innate immune defenses to HCV infection.     

MDA-5 is cleaved in poliovirus-infected cells

Infections with RNA viruses are sensed by the innate immune system through membrane-bound Toll-like receptors or the cytoplasmic RNA helicases RIG-I and MDA-5. It is believed that MDA-5 is crucial for sensing infections by picornaviruses, but there have been no studies on the role of this protein during infection with poliovirus, the prototypic picornavirus. Beginning at 4 h postinfection, MDA-5 protein is degraded in poliovirus-infected cells. Levels of MDA-5 declined beginning at 6 h after infection with rhinovirus type 1a or encephalomyocarditis virus, but the protein was stable in cells infected with rhinovirus type 16 or echovirus type 1. Cleavage of MDA-5 is not carried out by either poliovirus proteinase 2Apro or 3Cpro. Instead, degradation of MDA-5 in poliovirus-infected cells occurs in a proteasome- and caspase-dependent manner. Degradation of MDA-5 during poliovirus infection correlates with cleavage of poly(ADP) ribose polymerase (PARP), a hallmark of apoptosis. Induction of apoptosis by puromycin leads to cleavage of both PARP and MDA-5. The MDA-5 cleavage product observed in cells treated with puromycin is approximately 90 kDa, similar in size to the putative cleavage product observed in poliovirus-infected cells. Poliovirus-induced cleavage of MDA-5 may be a mechanism to antagonize production of type I interferon in response to viral infection.     

A type III effector protease NleC from enteropathogenic Escherichia coli targets NF-κB for degradation

Many bacterial pathogens utilize a type III secretion system (T3SS) to inject virulence effector proteins into host cells during infection. Previously, we found that enteropathogenic Escherichia coli (EPEC) uses the type III effector, NleE, to block the inflammatory response by inhibiting IκB degradation and nuclear translocation of the p65 subunit of NF-κB. Here we screened further effectors with unknown function for their capacity to prevent p65 nuclear translocation. We observed that ectopic expression of GFP-NleC in HeLa cells led to the degradation of p65. Delivery of NleC by the T3SS of EPEC also induced degradation of p65 in infected cells as well as other NF-κB components, c-Rel and p50. Recombinant His(6) -NleC induced p65 and p50 cleavage in HeLa cell lysates and mutation of a consensus zinc metalloprotease motif, HEIIH, abrogated NleC proteolytic activity. NleC inhibited IL-8 production during prolonged EPEC infection of HeLa cells in a protease activity-dependent manner. A double nleE/nleC mutant was further impaired for its ability to inhibit IL-8 secretion than either a single nleE or a single nleC mutant. We conclude that NleC is a type III effector protease that degrades NF-κB thereby contributing the arsenal of bacterial effectors that inhibit innate immune activation.     

Inhibition of cytoplasmic mRNA stress granule formation by a viral proteinase

Mammalian cells form dynamic cytoplasmic mRNA stress granules (SGs) in response to environmental stresses including viral infections. SGs are involved in regulating host mRNA function and metabolism, although their precise role during viral infection is unknown. SGs are thought to assemble based on functions of the RNA-binding proteins TIA-1/TIAR or Ras-GAP SH3 domain-binding protein (G3BP). Here, we investigated the relationship between a prototypical plus-strand RNA virus and SGs. Early during poliovirus infection, SG formation is induced, but as infection proceeds this ability is lost, and SGs disperse. Infection resulted in cleavage of G3BP, but not TIA-1 or TIAR, by poliovirus 3C proteinase. Expression of a cleavage-resistant G3BP restored SG formation during poliovirus infection and significantly inhibited virus replication. These results elucidate a mechanism for viral interference with mRNP metabolism and gene regulation and support a critical role of G3BP in SG formation and restriction of virus replication.     

Translation of polioviral mRNA is inhibited by cleavage of polypyrimidine tract-binding proteins executed by polioviral 3C(pro)

The translation of polioviral mRNA occurs through an internal ribosomal entry site (IRES). Several RNA-binding proteins, such as polypyrimidine tract-binding protein (PTB) and poly(rC)-binding protein (PCBP), are required for the poliovirus IRES-dependent translation. Here we report that a poliovirus protein, 3C(pro) (and/or 3CD(pro)), cleaves PTB isoforms (PTB1, PTB2, and PTB4). Three 3C(pro) target sites (one major target site and two minor target sites) exist in PTBs. PTB fragments generated by poliovirus infection are redistributed to the cytoplasm from the nucleus, where most of the intact PTBs are localized. Moreover, these PTB fragments inhibit polioviral IRES-dependent translation in a cell-based assay system. We speculate that the proteolytic cleavage of PTBs may contribute to the molecular switching from translation to replication of polioviral RNA.     

丙型肝炎病毒感染过程中其NS3/4A蛋白酶切割线粒体抗病毒信号蛋白的动态过程

已知丙型肝炎病毒(hepatitis C virus,HCV)可通过其蛋白酶NS3/4A切割线粒体抗病毒信号蛋白(mitochondrial antiviral signaling protein,MAVS)来逃逸天然免疫识别,但尚不清楚其切割动力学及切割在抑制干扰素中的作用。本研究旨在细胞模型中探讨HCV感染过程中病毒复制建立及病毒NS3/4A切割MAVS的动态过程,探究NS3/4A切割MAVS对病毒逃逸宿主天然免疫建立感染的贡献。首先构建基于绿色荧光蛋白(green fluorescent protein,GFP)的MAVS切割报告系统(GFP-NLS-MAVS-TM462),用 HCV Jc1-Gluc 感染Huh7.5/GFP-NLS-MAVS-TM462细胞。结果显示,病毒复制早期MAVS切割效率较低;NS3/4A高效切割MAVS发生于HCV复制晚期,且其切割效率与NS3蛋白水平相关。利用带有GFP ypet的HCV报告病毒Jc1-378-1感染Huh7.5/RFP-NLS-MAVS-TM462细胞,在单细胞水平观察HCV感染阳性细胞中MAVS被切割情况,发现HCV复制细胞中仅部分细胞MAVS被切割。进一步研究发现,不同基因型NS3/4A切割MAVS的效率仅与NS3表达水平相关。以上结果提示,HCV蛋白酶NS3/4A切割MAVS依赖NS3/4A蛋白在病毒复制过程中的累积,对在病毒复制早期逃逸宿主天然免疫建立感染可能无显著贡献。     

Cellular mRNA Decay Protein AUF1 Negatively Regulates Enterovirus and Human Rhinovirus Infections

To successfully complete their replication cycles, picornaviruses modify several host proteins to alter the cellular environment to favor virus production. One such target of viral proteinase cleavage is AU-rich binding factor 1 (AUF1), a cellular protein that binds to AU-rich elements, or AREs, in the 3′ noncoding regions (NCRs) of mRNAs to affect the stability of the RNA. Previous studies found that, during poliovirus or human rhinovirus infection, AUF1 is cleaved by the viral proteinase 3CD and that AUF1 can interact with the long 5′ NCR of these viruses in vitro. Here, we expand on these initial findings to demonstrate that all four isoforms of AUF1 bind directly to stem-loop IV of the poliovirus 5′ NCR, an interaction that is inhibited through proteolytic cleavage of AUF1 by the viral proteinase 3CD. Endogenous AUF1 was observed to relocalize to the cytoplasm of infected cells in a viral protein 2A-driven manner and to partially colocalize with the viral protein 3CD. We identify a negative role for AUF1 in poliovirus infection, as AUF1 inhibited viral translation and, ultimately, overall viral titers. Our findings also demonstrate that AUF1 functions as an antiviral factor during infection by coxsackievirus or human rhinovirus, suggesting a common mechanism that targets these related picornaviruses.     

Characterization of poliovirus 2A proteinase by mutational analysis: residues required for autocatalytic activity are essential for induction of cleavage of eukaryotic initiation factor 4F polypeptide p220.

The poliovirus proteinase 2A is autocatalytically released from the poliovirus polyprotein by cotranslational cleavage at its own amino terminus, resulting in separation of structural and nonstructural protein precursors. Cleavage is a prerequisite for further processing of the structural protein precursor and consequently for poliovirus encapsidation. A second function of 2Apro is in the rapid shutoff of host cell protein synthesis that occurs upon infection with poliovirus. This is associated with proteolytic cleavage of the p220 component of eukaryotic initiation factor eIF-4F, which is induced but not directly catalyzed by 2Apro. We introduced single-amino-acid substitutions in the 2Apro-coding region of larger poliovirus precursors that were subsequently translated in vitro and thus demonstrated that His-20, Asp-38, and Cys-109 (which constitute the putative catalytic triad) are essential for, and that His-117 is an important determinant of, the autocatalytic activity of 2Apro. This is consistent with the proposal that 2Apro is structurally related to a subclass of trypsinlike serine proteinases. Moreover, 2Apro containing a Cys109Ser substitution retained a small but significant autocatalytic activity. Cleavage of p220 was not induced by those mutants that had reduced proteolytic activity, indicating that the cellular factor that cleaves p220 is probably activated by 2Apro-catalyzed proteolytic cleavage.     

Proteolysis of the p220 component of the cap-binding protein complex is not sufficient for complete inhibition of host cell protein synthesis after poliovirus infection.

Infection of cells with poliovirus results in the complete shutoff of host protein synthesis. It is presumed that proteolysis of the p220 component of the cap-binding protein complex that is required for the translation of host mRNAs is responsible for the shutoff phenomenon. In this paper, we show that when cells are infected with poliovirus in the presence of guanidine or 3-methylquercetin, both inhibitors of poliovirus replication, complete cleavage of p220 occurs by 3.5 h postinfection. However, under these conditions only 55 to 77% of host protein synthesis is suppressed. Results obtained with extracts prepared from poliovirus-infected cells were similar to those obtained in vivo. These results suggest that complete inhibition of host protein synthesis after poliovirus infection requires at least one event in addition to proteolysis of p220. Thus, proteolysis of p220 is probably necessary but not sufficient for total suppression of host protein synthesis after poliovirus infection.     

Modification of cellular autophagy protein LC3 by poliovirus

Poliovirus infection remodels intracellular membranes, creating a large number of membranous vesicles on which viral RNA replication occurs. Poliovirus-induced vesicles display hallmarks of cellular autophagosomes, including delimiting double membranes surrounding the cytosolic lumen, acquisition of the endosomal marker LAMP-1, and recruitment of the 18-kDa host protein LC3. Autophagy results in the covalent lipidation of LC3, conferring the property of membrane association to this previously microtubule-associated protein and providing a biochemical marker for the induction of autophagy. Here, we report that a similar modification of LC3 occurs both during poliovirus infection and following expression of a single viral protein, a stable precursor termed 2BC. Therefore, one of the early steps in cellular autophagy, LC3 modification, can be genetically separated from the induction of double-membraned vesicles that contain the modified LC3, which requires both viral proteins 2BC and 3A. The existence of viral inducers that promote a distinct aspect of the formation of autophagosome-like membranes both facilitates the dissection of this cellular process and supports the hypothesis that this branch of the innate immune response is directly subverted by poliovirus.     

Failure of innate and adaptive immune responses in controlling hepatitis C virus infection

Effective innate and adaptive immune responses are essential for the control of hepatitis C virus (HCV) infection. Indeed, elimination of HCV during acute infection correlates with an early induction of innate and a delayed induction of adaptive immune responses. However, in the majority of acutely HCV-infected individuals, these responses are insufficient to clear the virus and persistence develops. In recent years, different mechanisms responsible for the failure of innate and adaptive immune responses have been identified. These include the proteolytic cleavage of molecules playing key roles in the induction of the interferon response, manipulation of interferon-induced effector proteins, interference with CD8+ T-cell function or immune escape in T- and B-cell epitopes. In this review, we discuss the possible roles of innate and adaptive immune responses in HCV clearance and the different evasion strategies used by the virus to escape these immune responses.     

Vpu mediates depletion of interferon regulatory factor 3 during HIV infection by a lysosome-dependent mechanism

HIV has evolved sophisticated mechanisms to avoid restriction by intracellular innate immune defenses that otherwise serve to control acute viral infection and virus dissemination. Innate defenses are triggered when pattern recognition receptor (PRR) proteins of the host cell engage pathogen-associated molecule patterns (PAMPs) present in viral products. Interferon regulatory factor 3 (IRF3) plays a central role in PRR signaling of innate immunity to drive the expression of type I interferon (IFN) and interferon-stimulated genes (ISGs), including a variety of HIV restriction factors, that serve to limit viral replication directly and/or program adaptive immunity. Productive infection of T cells by HIV is dependent upon the targeted proteolysis of IRF3 that occurs through a virus-directed mechanism that results in suppression of innate immune defenses. However, the mechanisms by which HIV controls innate immune signaling and IRF3 function are not defined. Here, we examined the innate immune response induced by HIV strains identified through their differential control of PRR signaling. We identified viruses that, unlike typical circulating HIV strains, lack the ability to degrade IRF3. Our studies show that IRF3 regulation maps specifically to the HIV accessory protein Vpu. We define a molecular interaction between Vpu and IRF3 that redirects IRF3 to the endolysosome for proteolytic degradation, thus allowing HIV to avoid the innate antiviral immune response. Our studies reveal that Vpu is an important IRF3 regulator that supports acute HIV infection through innate immune suppression. These observations define the Vpu-IRF3 interface as a novel target for therapeutic strategies aimed at enhancing the immune response to HIV.     

Cellular protein modification by poliovirus: the two faces of poly(rC)-binding protein

During picornavirus infection, several cellular proteins are cleaved by virus-encoded proteinases. Such cleavage events are likely to be involved in the changing dynamics during the intracellular viral life cycle, from viral translation to host shutoff to RNA replication to virion assembly. For example, it has been proposed that there is an active switch from poliovirus translation to RNA replication mediated by changes in RNA-binding protein affinities. This switch could be a mechanism for controlling template selection for translation and negative-strand viral RNA synthesis, two processes that use the same positive-strand RNA as a template but proceed in opposing directions. The cellular protein poly(rC)-binding protein (PCBP) was identified as a primary candidate for regulating such a mechanism. Among the four different isoforms of PCBP in mammalian cells, PCBP2 is required for translation initiation on picornavirus genomes with type I internal ribosome entry site elements and also for RNA replication. Through its three K-homologous (KH) domains, PCPB2 forms functional protein-protein and RNA-protein complexes with components of the viral translation and replication machinery. We have found that the isoforms PCBP1 and -2 are cleaved during the mid-to-late phase of poliovirus infection. On the basis of in vitro cleavage assays, we determined that this cleavage event was mediated by the viral proteinases 3C/3CD. The primary cleavage occurs in the linker between the KH2 and KH3 domains, resulting in truncated PCBP2 lacking the KH3 domain. This cleaved protein, termed PCBP2-DeltaKH3, is unable to function in translation but maintains its activity in viral RNA replication. We propose that through the loss of the KH3 domain, and therefore loss of its ability to function in translation, PCBP2 can mediate the switch from viral translation to RNA replication.     

Intracellular Vesicle Acidification Promotes Maturation of Infectious Poliovirus Particles

The autophagic pathway acts as part of the immune response against a variety of pathogens. However, several pathogens subvert autophagic signaling to promote their own replication. In many cases it has been demonstrated that these pathogens inhibit or delay the degradative aspect of autophagy. Here, using poliovirus as a model virus, we report for the first time bona fide autophagic degradation occurring during infection with a virus whose replication is promoted by autophagy. We found that this degradation is not required to promote poliovirus replication. However, vesicular acidification, which in the case of autophagy precedes delivery of cargo to lysosomes, is required for normal levels of virus production. We show that blocking autophagosome formation inhibits viral RNA synthesis and subsequent steps in the virus cycle, while inhibiting vesicle acidification only inhibits the final maturation cleavage of virus particles. We suggest that particle assembly, genome encapsidation, and virion maturation may occur in a cellular compartment, and we propose the acidic mature autophagosome as a candidate vesicle. We discuss the implications of our findings in understanding the late stages of poliovirus replication, including the formation and maturation of virions and egress of infectious virus from cells.     

Proteolytic cleavage of the catalytic subunit of DNA-dependent protein kinase during poliovirus infection

DNA-dependent protein kinase (DNA-PK) is a serine/threonine kinase that has critical roles in DNA double-strand break repair, as well as B- and T-cell antigen receptor rearrangement. The DNA-PK enzyme consists of the Ku regulatory subunit and a 450-kDa catalytic subunit termed DNA-PK(CS). Both of these subunits are autoantigens associated with connective tissue diseases such as systemic lupus erythematosus (SLE) and scleroderma. In this report, we show that DNA-PK(CS) is cleaved during poliovirus infection of HeLa cells. Cleavage was visible as early as 1.5 h postinfection (hpi) and resulted in an approximately 40% reduction in the levels of native protein by 5.5 hpi. Consistent with this observation, the activity of the DNA-PK(CS) enzyme was also reduced during viral infection, as determined by immunoprecipitation kinase assays. Although it has previously been shown that DNA-PK(CS) is a substrate of caspase-3 in vitro, the protein was still cleaved during poliovirus infection of the caspase-3-deficient MCF-7 cell line. Cleavage was not prevented by infection in the presence of a soluble caspase inhibitor, suggesting that cleavage in vivo was independent of host caspase activation. DNA-PK(CS) is directly cleaved by a picornaviral 2A protease in vitro, producing a fragment similar in size to the cleavage product observed in vivo. Taken together, our results indicate that DNA-PK(CS) is cleaved by the 2A protease during poliovirus infection. Proteolytic cleavage of DNA-PK(CS) during poliovirus infection may contribute to inhibition of host immune responses. Furthermore, cleavage of autoantigens by viral proteases may target these proteins for the autoimmune response by generating novel, or "immunocryptic," protein fragments.